Planet Cassandra

Big ScyllaDB Performance Gains on Google Cloud’s New Smaller Z3 Instances

16 July 2025, 2:00 pm by ScyllaDB

Benchmarks of ScyllaDB on Google Cloud’s new Z3 small instances achieved higher throughput and lower latency than N2 equivalents, especially under heavy load ScyllaDB recently had the privilege of examining Google Cloud’s shiny new small shape Z3 GCE instances in an early preview. The Z3 series is optimized for workloads that require low latency and high performance access to large data sets. Likewise, ScyllaDB is engineered to deliver predictable low latency, even with workloads exceeding millions of OPS per machine. Naturally, both ScyllaDB and Google Cloud were curious to see how these innovations translated to performance gains with data-intensive use cases. So, we partnered with Google Cloud to test ScyllaDB on the new instances. TL;DR When we tested ScyllaDB on these new Z3 small shape instances vs. the previous generation of N2 instances, we found significant throughput improvements as well as reduced latencies…particularly at high load scenarios. Why the New Z3 Instances Matter Z3 is Google Cloud’s first generation of Storage Optimized VMs, specifically designed to combine the latest CPU, memory, network, and high-density local SSD advancements. It introduces 36 TB of local SSD with up to 100 Gbps network throughput in its largest shape and brings in significant software-level improvements like partitioned placement policies, enhanced maintenance configurations, and optimized Hyperdisk support. The Z3 series has been available for over a year now. Previously, Z3 was only available in large configurations (88 and 176 vCPUs). With this new addition to the Z3 family, users can now choose from a broader range of high-performance instances, including shapes with 8, 16, 22, 32, and 44 vCPUs – all built on 4th Gen Intel Xeon Scalable (Sapphire Rapids), DDR5 memory, and local SSDs configured for maximum density and throughput. The new instance types — especially those in the 8 to 44 vCPU range — allow ScyllaDB to extend Z3 performance advantages to a broader set of workloads and customer profiles. And now that ScyllaDB X Cloud just introduced support for mixed-instance clusters, it’s the perfect timing for these new instances. Our customers can use them to expand and contract capacity with high precision. Or they can start small, then seamlessly shift to larger instances as their traffic grows. Test Methodology We evaluated the new Z3 instances against our current N2-based configurations using our standard weekly regression testing suite. These tests focus on measuring latency across a range of throughput levels, including an unthrottled phase to identify maximum operations per second. For all tests, each cluster consisted of 3 ScyllaDB nodes. The Z3 clusters used z3-highmem-16-highlssd instances, while the N2 clusters used n2-highmem-16 instances with attached 6 TB high-performance SSDs to match the Z3 clusters’ storage. Both instance families come with 16 vCPUs and 128 GB RAM. The replication factor was set to 3 to reflect our typical production setup. Four workloads were tested on ScyllaDB version 2025.1.2 with vnode-based keyspaces: Read (100% cache hit) Read (100% cache miss) Write Mixed (50% reads, 50% writes) For load generation, we used cassandra-stress with 1kb row size (one column). Each workload was progressively throttled to multiple fixed throughput levels, followed by an unthrottled phase. For throttled scenarios, we aimed for sub-millisecond to ~10ms latencies. For unthrottled loads, latency was disregarded to maximize throughput measurements. Benchmark Results First off, here’s an overview of the throughput results, combined: Now for the details… 1. Read Workload (100% Cache Hit) Latency results Load N2 P99 [ms] Z3 P99 [ms] 150k 0.64 0.5 300k 1.37 0.86 450k 7.23 6.23 600k Couldn’t meet op/s 10.02 700k Couldn’t meet op/s 13.1   The Z3 cluster consistently delivered better tail latencies across all load levels. For higher loads, the N2 based cluster couldn’t keep up, so we presented only results for the Z3 cluster. Maximum throughput results Load N2 Throughput Z3 Throughput Diff % Max 569,566 1,151,739 102   Due to superb performance gains from the CPU family upgrade, the Z3 cluster achieved a staggering 102% higher throughput than the N2 did at the unthrottled level. 2. Read Workload (100% Cache Miss) Latency results Load N2 P99 [ms] Z3 P99 [ms] 80k 2.53 2.02 165k 3.99 3.11 250k Couldn’t meet op/s 4.7   Again, the Z3 cluster achieved better latency results across all tested loads and could serve higher throughput while keeping latencies low. Maximum throughput results Load N2 Throughput Z3 Throughput Diff % Max 236,528 310,880 31   With a 100% cache read workload that’s bounded by a mix of disk and CPU performance, the Z3 cluster achieved a significant 31% gain in maximum throughput. 3. Write Workload Latency results Load N2 P99 [ms] Z3 P99 [ms] 200k 3.27 3.21 300k >100 ms 4.19   Although latencies remained relatively similar under moderate load, the N2 instances couldn’t sustain them under higher loads. Maximum throughput results Load N2 Throughput Z3 Throughput Diff % Max 349,995 407,951 17   Due to heavy compactions and intensive disk utilization, the write workload also takes advantage of Z3’s advancements. Here, it achieved 17% higher throughput. 4. Mixed Workload (50% Read / 50% Write) Latency results Load N2 P99 Write [ms] Z3 P99 Write [ms] N2 P99 Read [ms] Z3 P99 Read [ms] 50k 2.07 2.04 2.08 2.11 150k 2.27 2.65 2.65 2.93 300k 4.71 3.88 5.12 4.15 450k >100 ms 15.49 >100 ms 16.13 The Z3 cluster maintained similar latency characteristics to the N2 one in lower throughput ranges. In higher ones, it kept a consistent edge since it was able to serve data reliably at a wider range. Maximum throughput results Load N2 Throughput Z3 Throughput Diff % Max 519,154 578,380 11   With a 50% read:write ratio, the Z3 instances achieved 11% higher throughput for both read and write operations. Our Verdict on the New Z3 Instances The addition of Z3 smaller shapes brings new flexibility to ScyllaDB Cloud users. Whether you’re looking to scale down while retaining high SSD performance or ramp up throughput in cost-sensitive environments, Z3 offers a compelling alternative to N2. We’re excited to support the smaller Z3 instance types in ScyllaDB Cloud. These VMs will complement the existing N2 options and enable more flexible deployment profiles for workloads that demand high storage IOPS and network bandwidth without committing to extremely large core counts. What’s Next This first round of testing found that performance improvements on Z3 become significantly more pronounced as the load scales. We believe that stems from ScyllaDB’s ability to fully utilize the underlying hardware. Moving forward, we’ll continue validating Z3 under other scenarios (e.g., higher disk utilization, large partitions, compaction pressure, heterogeneous cluster mixing) and uplift our internal tuning recommendations accordingly.

Real-Time Machine Learning with ScyllaDB as a Feature Store

15 July 2025, 2:56 pm by ScyllaDB

What ML feature stores require and how ScyllaDB fits in as fast, scalable online feature store  In this blog post, we’ll explore the role of feature stores in real-time machine learning (ML) applications and why ScyllaDB is a strong choice for online feature serving. We’ll cover the basics of features, how feature stores work, their benefits, the different workload requirements, and how latency plays a critical role in ML applications. We’ll wrap up by looking at popular feature store frameworks like Feast and how to get started with ScyllaDB as your online feature store. What is a feature in machine learning? A feature is a measurable property used to train or serve a machine learning model. Features can be raw data points or engineered values derived from the raw data. For instance, in a social media app like ShareChat, features might include: Number of likes in the last 10 minutes Number of shares over the past 7 days Topic of the post Image credit: Ivan Burmistrov and Andrei Manakov (ShareChat) These data points help predict outcomes such as user engagement or content recommendation. A feature vector is simply a collection of features related to a specific prediction task. For example, this is what a feature vector could look like for a credit scoring application. zipcode person_age person_income loan_amount loan_int_rate (%) 94109 25 120000 10000 12 Selecting relevant data points and transforming them into features takes up a significant portion of the work in machine learning projects. It is also an ongoing process to refine and optimize features so the model being trained becomes more accurate over time. Feature store architectures In order to efficiently work with features, you can create a central place to manage the features that are available within your organization. A central feature store enables: A standard process to create new features Storage of features for simplified access Discovery and reuse of features across teams Serving features for both model training and inference Most architectures distinguish between two stores/databases: Offline store for model training (bulk writes/reads) Online store for inference (real-time, low-latency writes/reads) A typical feature store pipeline starts with ingesting raw data (from data lakes or streams), performing feature engineering, saving features in both stores, and then serving them through two separate pipelines: one for training and one for inference. Benefits of a centralized feature store Centralized feature stores offer several advantages: Avoid duplication: teams can reuse existing features Self-serve access: data scientists can generate and query features independently Unified pipelines: even though training and inference workloads are vastly different, they can still be queried using the same abstraction layer This results in faster iteration, more consistency, and better collaboration across ML workflows. Different workloads in feature stores Let’s break down the two very distinct workload requirements that exist within a feature store: model training and real-time inference. 1. Model training (offline store) In order to make predictions you need to train a machine learning model first. Training requires a large and high-quality dataset. You can store this dataset in an offline feature store. Here’s a run down of what characteristics matter most for model training workloads: Latency: Not a priority Volume: High (millions to billions of records) Frequency: Infrequent, scheduled jobs Purpose: Retrieve a large chunk of historical data Basically, offline stores need to efficiently store huge datasets. 2. Real-time inference (online store) Once you have a model ready, you can run real-time inference. Real-time inference takes the input provided by the user and turns it into a prediction. Here’s a look at what characteristics matter most for real-time inference: Latency: High priority Volume: Low per request but high throughput (up to millions of operations/second) Frequency: Constant, triggered by user actions (e.g. ordering food) Purpose: Serve up-to-date features for making predictions quickly For example, consider a food delivery app. The user’s recent cart contents, age, and location might be turned into features and used instantly to recommend other items to purchase. This would require real-time inference – and latency makes or breaks the user experience. Why latency matters Latency (in the context of this article) refers to the time between sending a query and receiving the response from the feature store. For real-time ML applications – especially user-facing ones– low latency is critical for success. Imagine a user at checkout being shown related food items. If this suggestion takes too long to load due to a slow online store, the opportunity is lost. The end-to-end flow from Ingesting the latest data Querying relevant features Running inference Returning a prediction must happen in milliseconds. Choosing a feature store solution Once you decide to build a feature store, you’ll quickly find that there are dozens of frameworks and providers, both open source and commercial, to choose from: Feast (open source): Provides flexible database support (e.g., Postgres, Redis, Cassandra, ScyllaDB) Hopsworks: Tightly coupled with its own ecosystem AWS SageMaker: Tied to the AWS stack (e.g., S3, DynamoDB) And lots of others Which one is best? Factors like your team’s technical expertise, latency requirements, and required integrations with your existing stack all play a role. There’s no one-size-fits-all solution. If you are worried about the scalability and performance of your online feature store, then database flexibility should be a key consideration. There are feature stores (e.g. AWS SageMaker, GCP Vertex, Hopsworks etc.) that provide their own database technology as the online store. On one hand, this might be convenient to get started because everything is handled by one provider. But this can also become a problem later on. Imagine choosing a vendor like this with a strict P99 latency requirement (e.g., <15ms P99). The requirement is successfully met during the proof of concept (POC). But later you experience latency spikes – maybe because your requirements change or there’s a surge of new users in your app or some other unpredictable reason. You want to switch to a different online store database backend to save costs. The problem is you cannot… at least not easily. You are stuck with the built-in solution. It’s unfeasible to migrate off just the online store part of your architecture because everything is locked in. If you want to avoid these situations, you can look into tools that are flexible regarding the offline and online store backend. Tools like Feast or FeatureForm allow you to bring your own database backend, both for the online and offline stores. This is a great way to avoid vendor lock-in and make future database migrations less painful in case latency spikes occur or costs rise. ScyllaDB as an online feature store ScyllaDB is a high-performance NoSQL database that’s API compatible with Apache Cassandra and DynamoDB API. It’s implemented in C++, uses a shard-per-core architecture, and includes an embedded cache system, making it ideal for low-latency, high-throughput feature store applications. Why ScyllaDB? Low latency (single-digit millisecond P99 performance) High availability and resilience High throughput at scale (petabyte-scale deployments) No vendor lock-in (runs on-prem or in any cloud) Drop-in replacement for existing Cassandra/DynamoDB setups Easy migration from other NoSQL databases (Cassandra, DynamoDB, MongoDB, etc) Integration with the feature store framework Feast ScyllaDB shines in online feature store use cases where real-time performance, availability, and latency predictability are critical. ScyllaDB + Feast integration Feast is a popular open-source feature store framework that supports both online and offline stores. One of its strengths is the ability to plug in your own database sources, including ScyllaDB. Read more about the ScyllaDB + Feast integration in the docs. Get started with a feature store tutorial Want to try using ScyllaDB as your online feature store? Check out our tutorials that walk you through the process of creating a ScyllaDB cluster and building a real-time inference application.  Tutorial: Price prediction inference app with ScyllaDB Tutorial: Real-time app with Feast & ScyllaDB Feast + ScyllaDB integration GitHub: ScyllaDB as a feature store code examples Have questions or want help setting it up? Submit a post in the forum!

Integrating support for AWS PrivateLink with Apache Cassandra® on the NetApp Instaclustr Managed Platform

15 July 2025, 12:00 pm by Apache Cassandra - Instaclustr

Discover how NetApp Instaclustr leverages AWS PrivateLink for secure and seamless connectivity with Apache Cassandra®. This post explores the technical implementation, challenges faced, and the innovative solutions we developed to provide a robust, scalable platform for your data needs.

Last year, NetApp achieved a significant milestone by fully integrating AWS PrivateLink support for Apache Cassandra® into the NetApp Instaclustr Managed Platform. Read our AWS PrivateLink support for Apache Cassandra General Availability announcement here. Our Product Engineering team made remarkable progress in incorporating this feature into various NetApp Instaclustr application offerings. NetApp now offers AWS PrivateLink support as an Enterprise Feature add-on for the Instaclustr Managed Platform for Cassandra, Kafka®, OpenSearch®, Cadence®, and Valkey™.

The journey to support AWS PrivateLink for Cassandra involved considerable engineering effort and numerous development cycles to create a solution tailored to the unique interaction between the Cassandra application and its client driver. After extensive development and testing, our product engineering team successfully implemented an enterprise ready solution. Read on for detailed insights into the technical implementation of our solution.

What is AWS PrivateLink?

PrivateLink is a networking solution from AWS that provides private connectivity between Virtual Private Clouds (VPCs) without exposing any traffic to the public internet. This solution is ideal for customers who require a unidirectional network connection (often due to compliance concerns), ensuring that connections can only be initiated from the source VPC to the destination VPC. Additionally, PrivateLink simplifies network management by eliminating the need to manage overlapping CIDRs between VPCs. The one-way connection allows connections to be initiated only from the source VPC to the managed cluster hosted in our platform (target VPC)—and not the other way around.

To get an idea of what major building blocks are involved in making up an end-to-end AWS PrivateLink solution for Cassandra, take a look at the following diagram—it’s a simplified representation of the infrastructure used to support a PrivateLink cluster:

In this example, we have a 3-node Cassandra cluster at the far right with one Cassandra node per Availability Zone (or AZ). Next, we have the VPC Endpoint Service and a Network Load Balancer (NLB). The Endpoint Service is essentially the AWS PrivateLink, and by design AWS needs it to be backed by an NLB–that’s pretty much what we have to manage on our side.

On the customer side, they must create a VPC Endpoint that enables them to privately connect to the AWS PrivateLink on our end; naturally, customers will also have to use a Cassandra client(s) to connect to the cluster.

AWS PrivateLink support with Instaclustr for Apache Cassandra

To incorporate AWS PrivateLink support with Instaclustr for Apache Cassandra on our platform, we came across a few technical challenges. First and foremost, the primary challenge was relatively straightforward: Cassandra clients need to talk to each individual node in a cluster.

However, the problem is that nodes in an AWS PrivateLink cluster are only assigned private IPs; that is what the nodes would announce by default when Cassandra clients attempt to discover the topology of the cluster. Cassandra clients cannot do much with the received private IPs as they cannot be used to connect to the nodes directly in an AWS PrivateLink setup.

We devised a plan of attack to get around this problem:

• Make each individual Cassandra node listen for CQL queries on unique ports.
• Configure the NLB so it can route traffic to the appropriate node based on the relevant unique port.
• Let clients implement the AddressTranslator interface from the Cassandra driver. The custom address translator will need to translate the received private IPs to one of the VPC Endpoint Elastic Network Interface (or ENI) IPs without altering the corresponding unique ports.

To understand this approach better, consider the following example:

Suppose we have a 3-node Cassandra cluster. According to the proposed approach we will need to do the followings:

• Let the nodes listen on ports 172.16.0.1:6001 (in AZ1), 172.16.0.2: 6002 (in AZ2) and 172.16.0.3: 6003 (in AZ3)
• Configure the NLB to listen on the same set of ports
• Define and associate target groups based on the port. For instance, the listener on port 6002 will be associated with a target group containing only the node that is listening on port 6002.
• As for how the custom address translator is expected to work, let’s assume the VPC Endpoint ENI IPs are 192.168.0.1 (in AZ1), 192.168.0.2 (in AZ2) and 192.168.0.3 (in AZ3). The address translator should translate received addresses like so:
  

  - 172.16.0.1:6001 --> 192.168.0.1:6001
  - 172.16.0.2:6002 --> 192.168.0.2:6002
  - 172.16.0.3:6003 --> 192.168.0.3:6003

The proposed approach not only solves the connectivity problem but also allows for connecting to appropriate nodes based on query plans generated by load balancing policies.

Around the same time, we came up with a slightly modified approach as well: we realized the need for address translation can be mostly mitigated if we make the Cassandra nodes return the VPC Endpoint ENI IPs in the first place.

But the excitement did not last for long! Why? Because we quickly discovered a key problem: there is a limit to the number of listeners that can be added to any given AWS NLB of just 50.

While 50 is certainly a decent limit, the way we designed our solution meant we wouldn’t be able to provision a cluster with more than 50 nodes. This was quickly deemed to be an unacceptable limitation as it is not uncommon for a cluster to have more than 50 nodes; many Cassandra clusters in our fleet have hundreds of nodes. We had to abandon the idea of address translation and started thinking about alternative solution approaches.

Introducing Shotover Proxy

We were disappointed but did not lose hope. Soon after, we devised a practical solution centred around using one of our open source products: Shotover Proxy.

Shotover Proxy is used with Cassandra clusters to support AWS PrivateLink on the Instaclustr Managed Platform.​ What is Shotover Proxy, you ask? Shotover is a layer 7 database proxy built to allow developers, admins, DBAs, and operators to modify in-flight database requests. By managing database requests in transit, Shotover gives NetApp Instaclustr customers AWS PrivateLink’s simple and secure network setup with the many benefits of Cassandra.

Below is an updated version of the previous diagram that introduces some Shotover nodes in the mix:

As you can see, each AZ now has a dedicated Shotover proxy node.

In the above diagram, we have a 6-node Cassandra cluster. The Cassandra cluster sitting behind the Shotover nodes is an ordinary Private Network Cluster. The role of the Shotover nodes is to manage client requests to the Cassandra nodes while masking the real Cassandra nodes behind them. To the Cassandra client, the Shotover nodes appear to be Cassandra nodes, and it is only them that make up the entire cluster! This is the secret recipe for AWS PrivateLink for Instaclustr for Apache Cassandra that enabled us to get past the challenges discussed earlier.

So how is this model made to work?

Shotover can alter certain requests from—and responses to—the client. It can examine the tokens allocated to the Cassandra nodes in its own AZ (aka rack) and claim to be the owner of all those tokens. This essentially makes them appear to be an aggregation of the nodes in its own rack.

Given the purposely crafted topology and token allocation metadata, while the client directs queries to the Shotover node, the Shotover node in turn can pass them on to the appropriate Cassandra node and then transparently send responses back. It is worth noting that the Shotover nodes themselves do not store any data.

Because we only have 1 Shotover node per AZ in this design and there may be at most about 5 AZs per region, we only need that many listeners in the NLB to make this mechanism work. As such, the 50-listener limit on the NLB was no longer a problem.

The use of Shotover to manage client driver and cluster interoperability may sound straight forward to implement, but developing it was a year-long undertaking. As described above, the initial months of development were devoted to engineering CQL queries on unique ports and the AddressTranslator interface from the Cassandra driver to gracefully manage client connections to the Cassandra cluster. While this solution did successfully provide support for AWS PrivateLink with a Cassandra cluster, we knew that the 50-listener limit on the NLB was a barrier for use and wanted to provide our customers with a solution that could be used for any Cassandra cluster, regardless of node count.

The next few months of engineering were then devoted to the Proof of Concept of an alternative solution with the goal to investigate how Shotover could manage client requests for a Cassandra cluster with any number of nodes. And so, after a solution to support a cluster with any number of nodes was successfully proved, subsequent effort was then devoted to work through stability testing the new solution, the results of that engineering being the stable solution described above.

We have also conducted performance testing to evaluate the relative performance of a PrivateLink-enabled Cassandra cluster compared to its non-PrivateLink counterpart. Multiple iterations of performance testing were executed as some adjustments to Shotover were identified from test cases and resulted in the PrivateLink-enabled Cassandra cluster throughput and latency measuring near to a standard Cassandra cluster throughput and latency.

Related content: Read more about creating an AWS PrivateLink-enabled Cassandra cluster on the Instaclustr Managed Platform

The following was our experimental setup for identifying the max throughput in terms of Operations per second of a Cassandra PrivateLink cluster in comparison to a non-Cassandra PrivateLink cluster

• Baseline node size: i3en.xlarge
• Shotover Proxy node size on Cassandra Cluster: CSO-PRD-c6gd.medium-54
• Cassandra version: 4.1.3
• Shotover Proxy version: 0.2.0
• Other configuration: Repair and backup disabled, Client Encryption disabled

Throughput results

Operation	Operation rate with PrivateLink and Shotover	Operation rate without PrivateLink
Mixed-small (3 Nodes)	16608	16206
Mixed-small (6 Nodes)	33585	33598
Mixed-small (9 Nodes)	51792	51798

Across different cluster sizes, we observed no significant difference in operation throughput between PrivateLink and non-PrivateLink configurations.

Latency results

Latency benchmarks were conducted at ~70% of the observed peak throughput (as above) to simulate realistic production traffic.

Operation	Ops/second	Setup	Mean Latency (ms)	Median Latency (ms)	P95 Latency (ms)	P99 Latency (ms)
Mixed-small (3 Nodes)	11630	Non-PrivateLink	9.90	3.2	53.7	119.4
		PrivateLink	9.50	3.6	48.4	118.8
Mixed-small (6 Nodes)	23510	Non-PrivateLink	6	2.3	27.2	79.4
		PrivateLink	9.10	3.4	45.4	104.9
Mixed-small (9 Nodes)	36255	Non-PrivateLink	5.5	2.4	21.8	67.6
		PrivateLink	11.9	2.7	77.1	141.2

Results indicate that for lower to mid-tier throughput levels, AWS PrivateLink introduced minimal to negligible overhead. However, at higher operation rates, we observed increased latency, most notably at the p99 mark—likely due to network level factors or Shotover.

The increase in latency is expected as AWS PrivateLink introduces an additional hop to route traffic securely, which can impact latencies, particularly under heavy load. For the vast majority of applications, the observed latencies remain within acceptable ranges. However, for latency-sensitive workloads, we recommend adding more nodes (for high load cases) to help mitigate the impact of the additional network hop introduced by PrivateLink.

As with any generic benchmarking results, performance may vary depending on specific data model, workload characteristics, and environment. The results presented here are based on specific experimental setup using standard configurations and should primarily be used to compare the relative performance of PrivateLink vs. Non-PrivateLink networking under similar conditions.

Why choose AWS PrivateLink with NetApp Instaclustr?

NetApp’s commitment to innovation means you benefit from cutting-edge technology combined with ease of use. With AWS PrivateLink support on our platform, customers gain:

• Enhanced security: All traffic stays private, never touching the internet.
• Simplified networking: No need to manage complex CIDR overlaps.
• Enterprise scalability: Handles sizable clusters effortlessly.

By addressing challenges, such as the NLB listener cap and private-to-VPC IP translation, we’ve created a solution that balances efficiency, security, and scalability.

Experience PrivateLink today

The integration of AWS PrivateLink with Apache Cassandra® is now generally available with production-ready SLAs for our customers. Log in to the Console to create a Cassandra cluster with support for AWS PrivateLink with just a few clicks today. Whether you’re managing sensitive workloads or demanding performance at scale, this feature delivers unmatched value.

Want to see it in action? Book a free demo today and experience the Shotover-powered magic of AWS PrivateLink firsthand.

Resources

• Getting started: Visit the documentation to learn how to create an AWS PrivateLink-enabled Apache Cassandra cluster on the Instaclustr Managed Platform.
• Connecting clients: Already created a Cassandra cluster with AWS PrivateLink? Click here to read about how to connect Cassandra clients in one VPC to an AWS PrivateLink-enabled Cassandra cluster on the Instaclustr Platform.
• General availability announcement: For more details, read our General Availability announcement on AWS PrivateLink support for Cassandra.

The post Integrating support for AWS PrivateLink with Apache Cassandra® on the NetApp Instaclustr Managed Platform appeared first on Instaclustr.

Netflix Tudum Architecture: from CQRS with Kafka to CQRS with RAW Hollow

10 July 2025, 7:31 pm by Netflix TechBlog - Medium

By Eugene Yemelyanau, Jake Grice

Introduction

Tudum.com is Netflix’s official fan destination, enabling fans to dive deeper into their favorite Netflix shows and movies. Tudum offers exclusive first-looks, behind-the-scenes content, talent interviews, live events, guides, and interactive experiences. “Tudum” is named after the sonic ID you hear when pressing play on a Netflix show or movie. Attracting over 20 million members each month, Tudum is designed to enrich the viewing experience by offering additional context and insights into the content available on Netflix.

Initial architecture

At the end of 2021, when we envisioned Tudum’s implementation, we considered architectural patterns that would be maintainable, extensible, and well-understood by engineers. With the goal of building a flexible, configuration-driven system, we looked to server-driven UI (SDUI) as an appealing solution. SDUI is a design approach where the server dictates the structure and content of the UI, allowing for dynamic updates and customization without requiring changes to the client application. Client applications like web, mobile, and TV devices, act as rendering engines for SDUI data. After our teams weighed and vetted all the details, the dust settled and we landed on an approach similar to Command Query Responsibility Segregation (CQRS). At Tudum, we have two main use cases that CQRS is perfectly capable of solving:

• Tudum’s editorial team brings exclusive interviews, first-look photos, behind the scenes videos, and many more forms of fan-forward content, and compiles it all into pages on the Tudum.com website. This content comes onto Tudum in the form of individually published pages, and content elements within the pages. In support of this, Tudum’s architecture includes a write path to store all of this data, including internal comments, revisions, version history, asset metadata, and scheduling settings.
• Tudum visitors consume published pages. In this case, Tudum needs to serve personalized experiences for our beloved fans, and accesses only the latest version of our content.

The high-level diagram above focuses on storage & distribution, illustrating how we leveraged Kafka to separate the write and read databases. The write database would store internal page content and metadata from our CMS. The read database would store read-optimized page content, for example: CDN image URLs rather than internal asset IDs, and movie titles, synopses, and actor names instead of placeholders. This content ingestion pipeline allowed us to regenerate all consumer-facing content on demand, applying new structure and data, such as global navigation or branding changes. The Tudum Ingestion Service converted internal CMS data into a read-optimized format by applying page templates, running validations, performing data transformations, and producing the individual content elements into a Kafka topic. The Data Service Consumer, received the content elements from Kafka, stored them in a high-availability database (Cassandra), and acted as an API layer for the Page Construction service and other internal Tudum services to retrieve content.

A key advantage of decoupling read and write paths is the ability to scale them independently. It is a well-known architectural approach to connect both write and read databases using an event driven architecture. As a result, content edits would eventually appear on tudum.com.

Challenges with eventual consistency

Did you notice the emphasis on “eventually?” A major downside of this architecture was the delay between making an edit and observing that edit reflected on the website. For instance, when the team publishes an update, the following steps must occur:

1. Call the REST endpoint on the 3rd party CMS to save the data.
2. Wait for the CMS to notify the Tudum Ingestion layer via a webhook.
3. Wait for the Tudum Ingestion layer to query all necessary sections via API, validate data and assets, process the page, and produce the modified content to Kafka.
4. Wait for the Data Service Consumer to consume this message from Kafka and store it in the database.
5. Finally, after some cache refresh delay, this data would eventually become available to the Page Construction service. Great!

By introducing a highly-scalable eventually-consistent architecture we were missing the ability to quickly render changes after writing them — an important capability for internal previews.

In our performance profiling, we found the source of delay was our Page Data Service which acted as a facade for an underlying Key Value Data Abstraction database. Page Data Service utilized a near cache to accelerate page building and reduce read latencies from the database.

This cache was implemented to optimize the N+1 key lookups necessary for page construction by having a complete data set in memory. When engineers hear “slow reads,” the immediate answer is often “cache,” which is exactly what our team adopted. The KVDAL near cache can refresh in the background on every app node. Regardless of which system modifies the data, the cache is updated with each refresh cycle. If you have 60 keys and a refresh interval of 60 seconds, the near cache will update one key per second. This was problematic for previewing recent modifications, as these changes were only reflected with each cache refresh. As Tudum’s content grew, cache refresh times increased, further extending the delay.

RAW Hollow

As this pain point grew, a new technology was being developed that would act as our silver bullet. RAW Hollow is an innovative in-memory, co-located, compressed object database developed by Netflix, designed to handle small to medium datasets with support for strong read-after-write consistency. It addresses the challenges of achieving consistent performance with low latency and high availability in applications that deal with less frequently changing datasets. Unlike traditional SQL databases or fully in-memory solutions, RAW Hollow offers a unique approach where the entire dataset is distributed across the application cluster and resides in the memory of each application process.

This design leverages compression techniques to scale datasets up to 100 million records per entity, ensuring extremely low latencies and high availability. RAW Hollow provides eventual consistency by default, with the option for strong consistency at the individual request level, allowing users to balance between high availability and data consistency. It simplifies the development of highly available and scalable stateful applications by eliminating the complexities of cache synchronization and external dependencies. This makes RAW Hollow a robust solution for efficiently managing datasets in environments like Netflix’s streaming services, where high performance and reliability are paramount.

Revised architecture

Tudum was a perfect fit to battle-test RAW Hollow while it was pre-GA internally. Hollow’s high-density near cache significantly reduces I/O. Having our primary dataset in memory enables Tudum’s various microservices (page construction, search, personalization) to access data synchronously in O(1) time, simplifying architecture, reducing code complexity, and increasing fault tolerance.

In our simplified architecture, we eliminated the Page Data Service, Key Value store, and Kafka infrastructure, in favor of RAW Hollow. By embedding the in-memory client directly into our read-path services, we avoid per-request I/O and reduce roundtrip time.

Migration results

The updated architecture yielded a monumental reduction in data propagation times, and the reduced I/O led to faster request times as an added bonus. Hollow’s compression alleviated our concerns about our data being “too big” to fit in memory. Storing three years’ of unhydrated data requires only a 130MB memory footprint — 25% of its uncompressed size in an Iceberg table!

Writers and editors can preview changes in seconds instead of minutes, while still maintaining high-availability and in-memory caching for Tudum visitors — the best of both worlds.

But what about the faster request times? The diagram below illustrates the before & after timing to fulfil a request for Tudum’s home page. All of Tudum’s read-path services leverage Hollow in-memory state, leading to a significant increase in page construction speed and personalization algorithms. Controlling for factors like TLS, authentication, request logging, and WAF filtering, homepage construction time decreased from ~1.4 seconds to ~0.4 seconds!

An attentive reader might notice that we have now tightly-coupled our Page Construction Service with the Hollow In-Memory State. This tight-coupling is used only in Tudum-specific applications. However, caution is needed if sharing the Hollow In-Memory Client with other engineering teams, as it could limit your ability to make schema changes or deprecations.

Key Learnings

1. CQRS is a powerful design paradigm for scale, if you can tolerate some eventual consistency.
2. Minimizing the number of sequential operations can significantly reduce response times. I/O is often the main enemy of performance.
3. Caching is complicated. Cache invalidation is a hard problem. By holding an entire dataset in memory, you can eliminate an entire class of problems.

In the next episode, we’ll share how Tudum.com leverages Server Driven UI to rapidly build and deploy new experiences for Netflix fans. Stay tuned!

Credits

Thanks to Drew Koszewnik, Govind Venkatraman Krishnan, Nick Mooney, George Carlucci

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Netflix Tudum Architecture: from CQRS with Kafka to CQRS with RAW Hollow was originally published in Netflix TechBlog on Medium, where people are continuing the conversation by highlighting and responding to this story.

Compaction Strategies, Performance, and Their Impact on Cassandra Node Density

10 July 2025, 12:00 am by Posts on RustyRazorblade Consulting

This is the third post in my series on optimizing Apache Cassandra for maximum cost efficiency through increased node density. In the first post, I examined how streaming operations impact node density and laid out the groundwork for understanding why higher node density leads to significant cost savings. In the second post, I discussed how compaction throughput is critical to node density and introduced the optimizations we implemented in CASSANDRA-15452 to improve throughput on disaggregated storage like EBS.

The Developer’s Data Modeling Cheat Guide​​​​‌‍​‍​‍‌‍‌​‍‌‍‍‌‌‍‌‌‍‍‌‌‍‍​‍​‍​‍‍​‍​‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌‍‍‌‌‍​‍​‍​‍​​‍​‍‌‍‍​‌​‍‌‍‌‌‌‍‌‍​‍​‍​‍‍​‍​‍‌‍‍​‌‌​‌‌​‌​​‌​​‍‍​‍​‍‌‍‌​‌‍​‌‌‌​‌‍​‌‌​‌‌​‌‍​‌‌‍​​‍‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌​‌‌​‌‌‌‌‍‌​‌‍‍‌‌‍​‍‌‍‍‌‌‍‍‌‌​‌‍‌‌‌‍‍‌‌​​‍‌‍‌‌‌‍‌​‌‍‍‌‌‌​​‍‌‍‌‌‍‌‍‌​‌‍‌‌​‌‌​​‌​‍‌‍‌‌‌​‌‍‌‌‌‍‍‌‌​‌‍​‌‌‌​‌‍‍‌‌‍‌‍‍​‍‌‍‍‌‌‍‌​​‌​‌​​‍‌‍​​‌‌​‌‌‍‌‍​​‌​‌‍​‍‌​‌‌‌‍​‌‍​‌​​‍​‍‌​‌​​‌​​‌​​‌‌​‍‌​‍‌​‌‌‍‌​​​​‍‌​​‌​‌​​‍‌​​​‌​​‌‍​‌​​‌‌‍‌‌‌‍​‌‌‍​​​‍​‍‌‌​‌‍‌‌​​‌‍‌‌​‌‌‍​‍‌‍​‌‍‌‍‌‌‌​​‌‍‌​‌‌​​‍‌​​‌‍​‌‌‌​‌‍‍​​‌‌‌​‌‍‍‌‌‌​‌‍​‌‍‌‌​‌‍​‍‌‍​‌‌​‌‍‌‌‌‌‌‌‌​‍‌‍​​‌‌‍‍​‌‌​‌‌​‌​​‌​​‍‌‌​​‌​​‌​‍‌‌​​‍‌​‌‍​‍‌‌​​‍‌​‌‍‌‍‌​‌‍​‌‌‌​‌‍​‌‌​‌‌​‌‍​‌‌‍​​‍‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌​‌‌​‌‌‌‌‍‌​‌‍‍‌‌‍​‍‌‍‌‍‍‌‌‍‌​​‌​‌​​‍‌‍​​‌‌​‌‌‍‌‍​​‌​‌‍​‍‌​‌‌‌‍​‌‍​‌​​‍​‍‌​‌​​‌​​‌​​‌‌​‍‌​‍‌​‌‌‍‌​​​​‍‌​​‌​‌​​‍‌​​​‌​​‌‍​‌​​‌‌‍‌‌‌‍​‌‌‍​​​‍​‍‌‍‌‌​‌‍‌‌​​‌‍‌‌​‌‌‍​‍‌‍​‌‍‌‍‌‌‌​​‌‍‌​‌‌​​‍‌‍‌​​‌‍​‌‌‌​‌‍‍​​‌‌‌​‌‍‍‌‌‌​‌‍​‌‍‌‌​‍‌‍‌​​‌‍‌‌‌​‍‌​‌​​‌‍‌‌‌‍​‌‌​‌‍‍‌‌‌‍‌‍‌‌​‌‌​​‌‌‌‌‍​‍‌‍​‌‍‍‌‌​‌‍‍​‌‍‌‌‌‍‌​​‍​‍‌‌

9 July 2025, 6:43 am by Datastax Technical HowTo's

In Cassandra 5.0, storage-attached indexes offer a new way to interact with your data, giving developers the flexibility to query multiple columns with filtering, range conditions, and better performance.

ScyllaDB’s Engineering Summit in Sofia, Bulgaria

2 July 2025, 1:01 pm by ScyllaDB

From hacking to hiking: what happens when engineering sea monsters get together  ScyllaDB is a remote-first company, with team members spread across the globe. We’re masters of virtual connection, but every year, we look forward to the chance to step away from our screens and come together for our Engineering Summit. It’s a time to reconnect, exchange ideas, and share spontaneous moments of joy that make working together so special. This year, we gathered in Sofia, Bulgaria — a city rich in history and culture, set against the stunning backdrop of the Balkan mountains. Where Monsters Meet This year’s summit brought together a record-breaking number of participants from across the globe—over 150! As ScyllaDB continues its continued growth, the turnout well reflects our momentum and our team’s expanding global reach. We, ScyllaDB Monsters from all corners of the world, came together to share knowledge, build connections, and collaborate on shaping the future of our company and product. A team-building activity An elevator ride to one of the sessions The summit brought together not just the engineering teams but also our Customer Experience (CX) colleagues. With their insights into the real-world experiences of our customers, the CX team helped us see the bigger picture and better understand how our work impacts those who use our product. The CX team Looking Inward, Moving Forward The summit was packed with really insightful talks, giving us a chance to reflect on where we are and where we’re heading next. It was all about looking back at the wins we’ve had so far, getting excited about the cool new features we’re working on now, and diving deep into what’s coming down the pipeline. CEO and Co-founder, Dor Laor, kicking off the summit The sessions sparked fruitful discussions about how we can keep pushing forward and build on the strong foundation we’ve already laid. The speakers touched on a variety of topics, including: ScyllaDB X Cloud Consistent topology Data distribution with tablets Object storage Tombstone garbage collection Customer stories Improving customer experience And many more Notes and focus doodles Collaboration at Its Best: The Hackathon This year, we took the summit energy to the next level with a hackathon that brought out the best in creativity, collaboration, and problem-solving. Participants were divided into small teams, each tackling a unique problem. The projects were chosen ahead of time so that we had a chance to work on real challenges that could make a tangible impact on our product and processes. The range of projects was diverse. Some teams focused on adding new features, like implementing a notification API to enhance the user experience. Others took on documentation-related challenges, improving the way we share knowledge. But across the board, every team managed to create a functioning solution or prototype. At the hackathon The hackathon brought people from different teams together to tackle complex issues, pushing everyone a bit outside their comfort zone. Beyond the technical achievements, it was a powerful team-building experience, reinforcing our culture of collaboration and shared purpose. It reminded us that solving real-life challenges—and doing it together—makes our work even more rewarding. The hackathon will undoubtedly be a highlight of future summits to come! From Development to Dance And then, of course, came the party. The atmosphere shifted from work to celebration with live music from a band playing all-time hits, followed by a DJ spinning tracks that kept everyone on their feet. Live music at the party Almost everyone hit the dance floor—even those who usually prefer to sit it out couldn’t resist the rhythm. It was the perfect way to unwind and celebrate the success of the summit! Sea monsters swaying Exploring Sofia and Beyond During our time in Sofia, we had the chance to immerse ourselves in the city’s rich history and culture. Framed by the dramatic Balkan mountains, Sofia blends the old with the new, offering a mix of history, culture, and modern vibe. We wandered through the ancient ruins of the Roman Theater and visited the iconic Alexander Nevsky Cathedral, marveling at their beauty and historical significance. To recharge our batteries, we enjoyed delicious meals in modern Bulgarian restaurants. In front of Alexander Nevsky Cathedral But the adventure didn’t stop in the city. We took a day trip to the Rila Mountains, where the breathtaking landscapes and serene atmosphere left us in awe. One of the standout sights was the Rila Monastery, a UNESCO World Heritage site known for its stunning architecture and spiritual significance. The Rila Monastery After soaking in the peaceful vibes of the monastery, we hiked the trail leading to the Stob Earth Pyramids, a natural wonder that looked almost otherworldly. The Stob Pyramids The hike was rewarding, offering stunning views of the mountains and the unique rock formations below. It was the perfect way to experience Bulgaria’s natural beauty while winding down from the summit excitement. Happy hiking Looking Ahead to the Future As we wrapped up this year’s summit, we left feeling energized by the connections made, ideas shared, and challenges overcome. From brainstorming ideas to clinking glasses around the dinner table, this summit was a reminder of why in-person gatherings are so valuable—connecting not just as colleagues but as a team united by a common purpose. As ScyllaDB continues to expand, we’re excited for what lies ahead, and we can’t wait to meet again next year. Until then, we’ll carry the lessons, memories, and new friendships with us as we keep moving forward. Чао! We’re hiring – join our team! Our team

How ScyllaDB Simulates Real-World Production Workloads with the Rust-Based “latte” Benchmarking Tool

1 July 2025, 12:21 pm by ScyllaDB

Learn why we use a little-known benchmarking tool for testing Before using a tech product, it’s always nice to know its capabilities and limits. In the world of databases, there are a lot of different benchmarking tools that help us assess that… If you’re ok with some standard benchmarking scenarios, you’re set – one of the existing tools will probably serve you well. But what if not? Rigorously assessing ScyllaDB, a high-performance distributed database, requires testing some rather specific scenarios, ones with real-world production workloads. Fortunately, there is a tool to help with that. It is latte: a Rust-based lightweight benchmarking tool for Apache Cassandra and ScyllaDB.

Special thanks to Piotr Kołaczkowski for implementing the latte benchmarking tool.

We (the ScyllaDB testing team) forked it and enhanced it. In this blog post, I’ll share why and how we adopted it for our specialized testing needs. About latte Our team really values latte’s “flexibility.” Want to create a schema using a user defined type (UDT), Map, Set, List, or any other data type? Ok. Want to create a materialized views and query it? Ok. Want to change custom function behavior based on elapsed time? Ok. Want to run multiple custom functions in parallel? Ok. Want to use small, medium, and large partitions? Ok. Basically, latte lets us define any schema and workload functions. We can do this thanks to its implementation design. The latte tool is a type of engine/kernel and rune scripts are essentially the “business logic” that’s written separately. Rune scripts are an enhanced, more powerful, analog of what cassandra-stress calls user profiles. The rune scripting language is dynamically-typed and native to the Rust programming language ecosystem. Here’s a simple example of a rune script: In the above example of a rune script, we defined 2 required functions (schema and prepare) and one custom to be used as our workload –myinsert. First, we create a schema: Then, we use the latte run command to call our custom myinsert function: The replication_factor parameter above is a custom parameter. If we do not specify it, then latte will use its default value, 3. We can define any number of custom parameters. How is latte different from other benchmarking Tools? Based on our team’s experiences, here’s how latte compares to the 2 main competitors: cassandra-stress and ycsb: How is our fork of latte different from the original latte project? At ScyllaDB, our main use case for latte is testing complex and realistic customer scenarios with controlled disruptions. But (from what we understand), the project was designed to perform general latency measurements in healthy DB clusters. Given these different goals, we changed some features (“overlapping features”) – and added other new ones (“unique to our fork”). Here’s an overview: Overlapping features differences Latency measurement. Fork-latte accounts for coordinated omission in latencies The original project doesn’t consider the “coordinated omission” phenomenon. Saturated DB impact. When a system under test cannot keep up with the load/stress, fork-latte tries to satisfy the “rate”, compensating for missed scheduler ticks ASAP. Source-latte pulls back on violating the rate requirement and doesn’t later compensate for missed scheduler ticks. This isn’t a “bug”; it is a design decision which also violates the idea of proper latency calculation related to the “coordinated omission” phenomenon. Retries. We enabled retries by default; there, it is disabled by default. Prepared statements. Fork-latte supports all the CQL data types available in ScyllaDB Rust Driver. The source project has limited support of CQL data types. ScyllaDB Rust Driver. Our fork uses the latest version – “1.2.0” The source project sticks to the old version “0.13.2” Stress execution reporting. Report is disabled by default in fork-latte. It’s enabled in source-latte. Features unique to our fork Preferred datacenter support. Useful for testing multi-DC DB setups Preferred rack support. Useful for testing multi-rack DB setups Possibility to get a list of actual datacenter values from the DB nodes that the driver connected to. Useful for creating schema with dc-based keyspaces Sine-wave rate limiting. Useful for SLA/Workload Prioritization demo and OLTP testing with peaks and lows. Batch query type support. Multi-row partitions. Our fork can create multi-row partitions of different sizes. Page size support for select queries. Useful using multi-row partitions feature. HDR histograms support. The source project has only 1 way to get the HDR histograms data It stores HDR histograms data in RAM till the end of a stress command execution and only in the end releases it as part of a report. Leaks RAM. Forked latte supports the above inherited approach and one more: Real-time streaming of HDR histogram data not storing in RAM. No RAM leaks. Rows count validation for select queries. Useful for testing data resurrection.   Example: Testing multi-row partitions of different sizes Let’s look at one specific user scenario where we applied our fork of latte to test ScyllaDB. For background, one of the user’s ScyllaDB production clusters was using large partitions which could be grouped by size in 3 groups: 2000, 4000 and 8000 rows per partition. 95% of the partitions had 2000 rows, 4% of partitions had 4000 rows, and the last 1% of partitions had 8000 rows. The target table had 20+ different columns of different types. Also, ScyllaDB’s Secondary Indexes (SI) feature was enabled for the target table. One day, on one of the cloud providers, latencies spiked and throughput dropped. The source of the problem was not immediately clear. To learn more, we needed to have a quick way to reproduce the customer’s workload in a test environment. Using the latte tool and its great flexibility, we created a rune script covering all the above specifics. The simplified rune script looks like the following: Assume we have a ScyllaDB cluster where one of the nodes has a 172.17.0.2 IP address. Here is the command to create the schema we need: And here is the command to populate the just-created table: To read from the main table and from the MV, use a similar command – just replacing the function name to get and get_from_mv respectively. So, the usage of the above commands allowed us to get a stable issue reproducer and work on its solution. Working with ScyllaDB’s Workload Prioritization feature In other cases, we needed to: Create a Workload Prioritization (WLP) demo. Test an OLTP setup with continuous peaks and lows to showcase giving priority to different workloads. And for these scenarios, we used a special latte feature called sine wave rate. This is an extension to the common rate-limiting feature. It allows us to specify how many operations per second we want to produce. It can be used with following command parameters: And looking at the monitoring, we can see the following picture of the operations per second graph: Internal testing of tombstones (validation) As of June 2025, forked latte supports row count validation. It is useful for testing data resurrection. Here is the rune script for latte to demonstrate these capabilities: As before, we create the schema first: Then, we populate the table with 100k rows using the following command: To check that all rows are in place, we use command similar to the one above, change the function to be get, and define the validation strategy to be fail-fast: The supported validation strategies are retry, fail-fast, ignore. Then, we run 2 different commands in parallel. Here is the first one, which deletes part of the rows: Here is the second one, which knows when we expect 1 row and when we expect none: And here is the timing of actions that take place during these 2 commands’ runtime: That’s a simple example of how we can check whether data got deleted or not. In long-running testing scenarios, we might run more parallel commands, make them depend on the elapsed time, and many more other flexibilities. Conclusions Yes, to take advantage of latte, you first need to study a bit of  rune scripting. But once you’ve done that to some extent, especially having available examples, it becomes a powerful tool that is capable of covering various scenarios of different types.

ScyllaDB Tablets: Answering Your Top Questions

24 June 2025, 12:05 pm by ScyllaDB

What does your team need to know about tablets– at a purely pragmatic level? Here are answers to the top user questions. The latest ScyllaDB releases feature some significant architectural shifts. Tablets build upon a multi-year project to re-architect our legacy ring architecture. And our metadata is now fully consistent, thanks to the assistance of Raft. Together, these changes can help teams with elasticity, speed, and operational simplicity. Avi Kivity, our CTO and co-founder, provided a detailed look at why and how we made this shift in a series of blogs (Why ScyllaDB Moved to “Tablets” Data Distribution and How We Implemented ScyllaDB’s “Tablets” Data Distribution). Join Avi for a technical deep dive…at our upcoming livestream And we recently created this quick demo to show you what this looks like in action, from the point of view of a database user/operator: But what does your team need to know – at a purely pragmatic level? Here are some of the questions we’ve heard from interested users, and a short summary of how we answer them. What’s the TL;DR on tablets? Tablets are the smallest replication unit in ScyllaDB. Data gets distributed by splitting tables into smaller logical pieces called tablets, and this allows ScyllaDB to shift from a static to a dynamic topology. Tablets are dynamically balanced across the cluster using the Raft consensus protocol. This was introduced as part of a project to bring more elasticity to ScyllaDB, enabling faster topology changes and seamless scaling. Tablets acknowledge that most workloads do not follow a static traffic pattern. In fact, most often follow a cyclical curve with different baseline and peaks through a period of time. By decoupling topology changes from the actual streaming of data, tablets therefore present significant cost saving opportunities for users adopting ScyllaDB by allowing infrastructure to be scaled on-demand, fast. Previously, adding or removing nodes required a sequential, one-at-a-time and serializable process with data streaming and rebalancing. Now, you can add or remove multiple nodes in parallel. This significantly speeds up the scaling process and makes ScyllaDB much more elastic. Tablets are distributed on a per-table basis, with each table having its own set of tablets. The tablets are then further distributed across the shards in the ScyllaDB cluster. The distribution is handled automatically by ScyllaDB, with tablets being dynamically migrated across replicas as needed. Data within a table is split across tablets based on the average geometric size of a token range boundary. How do I configure tablets? Tablets are enabled by default in ScyllaDB 2025.1 and are also available with ScyllaDB Cloud. When creating a new keyspace, you can specify whether to enable tablets or not. There are also three key configuration options for tablets: 1) the enable_tablets boolean setting, 2) the target_tablet_size_in_bytes (default is 5GB), and 3) the tablets property during a CREATE KEYSPACE statement. Here are a few tips for configuring these settings: enable_tablets indicates whether newly created keyspaces should rely on tablets for data distribution. Note that tablets are currently not yet enabled for workloads requiring the use of Counters Tables, Secondary Indexes, Materialized Views, CDC, or LWT. target_tablet_size_in_bytes indicates the average geometric size of a tablet, and is particularly useful during tablet split and merge operations. The default indicates splits are done when a tablet reaches 10GB and merges at 2.5GB. A higher value means tablet migration throughput can be reduced (due to larger tablets), whereas a lower value may significantly increase the number of tablets. The tablets property allows you to opt for tablets on a per keyspace basis via the ‘enabled’ boolean sub-option. This is particularly important if some of your workloads rely on the currently unsupported features mentioned earlier: You may opt out for these tables and fallback to the still supported vNode-based replication strategy. Still under the tablets property, the ‘initial’ sub-option determines how many tablets are created upfront on a per-table basis. We recommend that you target 100 tablets/shard. In future releases, we’ll introduce Per-table tablet options to extend and simplify this process while deprecating the keyspace sub-option. How/why should I monitor tablet distribution? Starting with ScyllaDB Monitoring 4.7, we introduced two additional panels for the observability and distribution of tablets within a ScyllaDB cluster. These metrics are present within the Detailed dashboard under the Tablets section: The Tablets over time panel is a heatmap showing the tablet distribution over time. As the data size of a tablet-enabled table grows, you should observe the number of tablets increasing (tablet split) and being automatically distributed by ScyllaDB. Likewise, as the table size shrinks, the number of tablets should be reduced (tablet merge, but to no less than your initially configured ‘initial’ value within the keyspace tablets property). Similarly, as you perform topology changes (e.g., adding nodes), you can monitor the tablet distribution progress. You’ll notice that existing replicas will have their tablet count reduced while new replicas will increase. The Tablets per DC/Instance/Shard panel shows the absolute count of tablets within the cluster. Under heterogeneous setups running on top of instances of the same size, this metric should be evenly balanced. However, the situation changes for heterogeneous setups with different shard counts. In this situation, it is expected that larger instances will hold more tablets given their additional processing power. This is, in fact, yet another benefit of tablets: the ability to run heterogeneous setups and leave it up to the database to determine how to internally maximize each instance’s performance capabilities. What are the impacts of tablets on maintenance tasks like node cleanup? The primary benefit of tablets is elasticity. Tablets allow you to easily and quickly scale out and in your database infrastructure without hassle. This not only translates to infrastructure savings (like avoiding being overprovisioned for the peak all the time). It also allows you to reach a higher percentage of storage utilization before rushing to add more nodes – so you can better utilize the underlying infrastructure you pay for. Another key benefit of tablets is that they eliminate the need for maintenance tasks like node cleanup. Previously, after scaling out the cluster, operators would need to run node cleanup to ensure data was properly evicted from nodes that no longer owned certain token ranges. With tablets, this is no longer necessary. The compaction process automatically handles the migration of data as tablets are dynamically balanced across the cluster. This is a significant operational improvement that reduces the maintenance burden for ScyllaDB users. The ability to now run heterogeneous deployments without running through cryptic and hours-long tuning cycles is also a plus. ScyllaDB’s tablet load balancer is smart enough to figure out how to distribute and place your data. It considers the amount of compute resources available, reducing the risk of traffic hotspots or data imbalances that may affect your clusters’ performance. In the future, ScyllaDB will bring transparent repairs on a per-tablet basis, further eliminating the need for users to worry about repairing their clusters, and also provide “temperature-based balancing” so that hot partitions get split and other shards cooperate with the incoming load. Do I need to change drivers? ScyllaDB’s latest drivers are tablet-aware, meaning they understand the tablets concept and can route queries to the correct nodes and shards. However, the drivers do not directly query the internal system.tablets table. That could become unwieldy as the number of tablets grows. Furthermore, tablets are transient, meaning a replica owning a tablet may no longer be a natural endpoint for it as time goes by. Instead, the drivers use a dynamic routing process: when a query is sent to the wrong node/shard, the coordinator will respond with the correct routing information, allowing the driver to update its routing cache. This ensures efficient query routing as tablets are migrated across the cluster. When using ScyllaDB tablets, it’s more important than ever to use ScyllaDB shard-aware – and now also tablet-aware – drivers instead of Cassandra drivers. The existing drivers will still work, but they won’t work as efficiently because they lack the necessary logic to understand the coordinator-provided tablet metadata. Using the latest ScyllaDB drivers should provide a nice throughput and latency boost. Read more in How We Updated ScyllaDB Drivers for Tablets Elasticity. More questions? If you’re interested in tablets and we didn’t answer your question here, please reach out to us! Our Contact Us page offers a number of ways to interact, including a community forum and Slack.  

Introducing ScyllaDB X Cloud: A (Mostly) Technical Overview

17 June 2025, 12:10 pm by ScyllaDB

ScyllaDB X Cloud just landed! It’s a truly elastic database that supports variable/unpredictable workloads with consistent low latency, plus low costs. The ScyllaDB team is excited to announce ScyllaDB X Cloud, the next generation of our fully-managed database-as-a-service. It features architectural enhancements for greater flexibility and lower cost. ScyllaDB X Cloud is a truly elastic database designed to support variable/unpredictable workloads with consistent low latency as well as low costs. A few spoilers before we get into the details: You can now scale out and scale in almost instantly to match actual usage, hour by hour. For example, you can scale all the way from 100K OPS to 2M OPS in just minutes, with consistent single-digit millisecond P99 latency. This means you don’t need to overprovision for the worst-case scenario or suffer latency hits while waiting for autoscaling to fully kick in. You can now safely run at 90% storage utilization, compared to the standard 70% utilization. This means you need fewer underlying servers and have substantially less infrastructure to pay for. Optimizations like file-based streaming and dictionary-based compression also speed up scaling and reduce network costs. Beyond the technical changes, there’s also an important pricing update. To go along with all this database flexibility, we’re now offering a “Flex Credit” pricing model. Basically, this gives you the flexibility of on-demand pricing with the cost advantage that comes from an annual commitment. Access ScyllaDB X Cloud Now If you want to get started right away, just go to ScyllaDB Cloud and choose the X Cloud cluster type when you create a cluster. This is our code name for the new type of cluster that enables greater elasticity, higher storage utilization, and automatic scaling. Note that X Cloud clusters are available from the ScyllaDB Cloud application (below) and API. They’re available on AWS and GCP, running on a ScyllaDB account or your company’s account with the Bring Your Own Account (BYOA) model. Sneak peek: In the next release, you won’t need to choose instance size or number of services if you select the X Cloud option. Instead, you will be able to define a serverless scaling policy and let X Cloud scale the cluster as required. If you want to learn more, keep reading. In this blog post, we’ll cover what’s behind the technical changes and also talk a little about the new pricing option. But first, let’s start with the why. Backstory Why did we do this? Consider this example from a marketing/AdTech platform that provides event-based targeting. Such a pattern, with predictable/cyclical daily peaks and low baseline off-hours, is quite common across retail platforms, food delivery services, and other applications aligned with customer work hours. In this case, the peak loads are 3x the base and require 2-3x the resources. With ScyllaDB X Cloud, they can provision for the baseline and quickly scale in/out as needed to serve the peaks. They get the steady low latency they need without having to overprovision – paying for peak capacity 24/7 when it’s really only needed for 4 hours a day. Tablets + just-in-time autoscaling If you follow ScyllaDB, you know that tablets aren’t new. We introduced them last year for ScyllaDB Enterprise (self-managed on the cloud or on-prem). Avi Kivity, our CTO, already provided a look at why and how we implemented tablets. And you can see tablets in action here: With tablets, data gets distributed by splitting tables into smaller logical pieces (“tablets”), which are dynamically balanced across the cluster using the Raft consensus protocol. This enables you to scale your databases as rapidly as you can scale your infrastructure. In a self-managed ScyllaDB deployment, tablets makes it much faster and simpler to expand and reduce your database capacity. However, you still need to plan ahead for expansion and initiate the operations yourself. ScyllaDB X Cloud lets you take full advantage of tablets’ elasticity. Scaling can be triggered automatically based on storage capacity (more on this below) or based on your knowledge of expected usage patterns. Moreover, as capacity expands and contracts, we’ll automatically optimize both node count and utilization. You don’t even have to choose node size; ScyllaDB X Cloud’s storage-utilization target does that for you. This should simplify admin and also save costs. 90% storage utilization ScyllaDB has always handled running at 100% compute utilization well by having automated internal schedulers manage compactions, repairs, and lower-priority tasks in a way that prioritizes performance. Now, it also does two things that let you increase the maximum storage utilization to 90%: Since tablets can move data to new nodes so much faster, ScyllaDB X Cloud can defer scaling until the very last minute Support for mixed instance sizes allows ScyllaDB X Cloud to allocate minimal additional resources to keep the usage close to 90% Previously, we recommended adding nodes at 70% capacity. This was because node additions were unpredictable and slow — sometimes taking hours or days — and you risked running out of space. We’d send a soft alert at 50% and automatically add nodes at 70%. However, those big nodes often sat underutilized. With ScyllaDB X Cloud’s tablets architecture, we can safely target 90% utilization. That’s particularly helpful for teams with storage-bound workloads. Support for mixed size clusters A little more on the “mixed instance size” support mentioned earlier. Basically, this means that ScyllaDB X Cloud can now add the exact mix of nodes you need to meet the exact capacity you need at any given time. Previous versions of ScyllaDB used a single instance size across all nodes in the cluster. For example, if you had a cluster with 3 i4i.16xlarge instances, increasing the capacity meant adding another i4i.16xlarge. That works, but it’s wasteful: you’re paying for a big node that you might not immediately need. Now with ScyllaDB X Cloud (thanks to tablets and support for mixed-instance sizes), we can scale in much smaller increments. You can add tiny instances first, then replace them with larger ones if needed. That means you rarely pay for unused capacity. For example, before, if you started with an i4i.16xlarge node that had 15 TB of storage and you hit 70% utilization, you had to launch another i4i.16xlarge — adding 15 TB at once. With ScyllaDB X Cloud, you might add two xlarge nodes (2 TB each) first. Then, if you need more storage, you add more small nodes, then eventually replace them with larger nodes. And by the way, i7i instances are now available too, and they are even more powerful. The key is granular, just-in-time scaling: you only add what you need, when you need it. This applies in reverse, too. Before, you had to decommission a large node all at once. Now, ScyllaDB X Cloud can remove smaller nodes gradually based on the policies you set, saving compute and storage costs. Network-focused engineering optimizations Every gigabyte leaving a node, crossing an Availability Zone (AZ) boundary, or replicating to another region shows up on your AWS, GCP, or Azure bill. That’s why we’ve done some engineering work at different layers of ScyllaDB to shrink those bytes—and the dollars tied to them. File-based streaming We anticipated that mutation-based streaming would hold us back once we moved to tablets. So we shifted to a new approach: stream the entire SSTable files without deserializing them into mutation fragments and re-serializing them back into SSTables on receiving nodes. As a result, less data is streamed over the network and less CPU is consumed, especially for data models that contain small cells. Think of it as Cassandra’s zero-copy streaming, except that we keep ownership metadata with each replica. This table shows the result: You can read more about this in the blog Why We Changed ScyllaDB’s Data Streaming Approach. Dictionary-based compression We also introduced dictionary-trained Zstandard (Zstd), which is pipeline-aware. This involved building a custom RPC compressor with external dictionary support, and a mechanism that trains new dictionaries on RPC traffic, distributes them over the cluster, and performs a live switch of connections to the new dictionaries. This is done in 4 key steps: Sample: Continuously sample RPC traffic for some time Train: Train a 100 kiB dictionary on a 16MiB sample Distribute: Distribute a new dictionary via system distributed table Switch: Negotiate the switch separately within each connection On the graph below, you can see LZ4 (Cassandra’s default) leaves you at 72% of the original size. Generic Zstd cuts that to 50%. Our per-cluster Zstd dictionary takes it down to 30%, which is a 3X improvement over the default Cassandra compression. Flex Credit To close, let’s shift from the technical changes to a major pricing change: Flex Credit. Flex Credit is a new way to consume a ScyllaDB Cloud subscription. It can be applied to ScyllaDB Cloud as well as ScyllaDB Enterprise. Flex Credit provides the flexibility of on-demand pricing at a lower cost via an annual commitment. In combination with X Cloud, Flex Credit can be a great tool to reduce cost. You can use Reserved pricing for a load that’s known in advance and use Flex for less predictable bursts. This saves you from paying the higher on-demand pricing for anything above the reserved part. How might this play out in your day-to-day work? Imagine your baseline workload handles 100K OPS, but sometimes it spikes to 400K OPS. Previously, you’d have to provision (and pay for) enough capacity to sustain 400K OPS at all times. That’s inefficient and costly. With ScyllaDB X Cloud, you reserve 100K OPS upfront. When a spike hits, we automatically call the API to spin up “flex capacity” – instantly scaling you to 400K OPS – and then tear it down when traffic subsides. You only pay for the extra capacity during the peak. Not sure what to choose? We can help advise based on your workload specifics (contact your representative or ping us here), but here’s some quick guidance in the meantime. Reserved Capacity: The most cost-effective option across all plans. Commit to a set number of cluster nodes or machines for a year. You lock in lower rates and guarantee capacity availability. This is ideal if your cluster size is relatively stable. Hybrid Model: Reserved + On-Demand: Commit to a baseline reserved capacity to lock in lower rates, but if you exceed that baseline (e.g., because you have a traffic spike), you can scale with on-demand capacity at an hourly rate. This is good if your usage is mostly stable but occasionally spikes. Hybrid Model: Reserved + Flex Credit: Commit to baseline reserved capacity for the lowest rates. For peak usage, use pre-purchased flex credit (which is discounted) instead of paying on-demand prices. Flex credit also applies to network and backup usage at standard provider rates. This is ideal if you have predictable peak periods (e.g., seasonal spikes, event-driven workload surges, etc.). You get the best of both worlds: low baseline costs and cost-efficient peak capacity. Recap In summary, ScyllaDB X Cloud uses tablets to enable faster, more granular scaling with mixed-instance sizes. This lets you avoid overprovisioning and safely run at 90% storage utilization. All of this will help you respond to volatile/unpredictable demand with low latencies and low costs. Moreover, flexible pricing (on-demand, flex credit, reserved) will help you pay only for what you need, especially when you have tablets scaling your capacity up and down in response to traffic spikes. There are also some network cost optimizations through file-based streaming and improved compression. Want to learn more? Our Co-Founder/CTO Avi Kivity will be discussing the design decisions behind ScyllaDB X Cloud’s elasticity and efficiency. Join us for the engineering deep dive on July 10. ScyllaDB X Cloud: An Inside Look with Avi Kivity

A New Way to Estimate DynamoDB Costs

10 June 2025, 1:11 pm by ScyllaDB

We built a new DynamoDB cost analyzer that helps developers understand what their workloads will really cost DynamoDB costs can blindside you. Teams regularly face “bill shock”: that sinking feeling when you look at a shockingly high bill and realize that you haven’t paid enough attention to your usage, especially with on-demand pricing. Provisioned capacity brings a different risk: performance. If you can’t accurately predict capacity or your math is off, requests get throttled. It’s a delicate balancing act. Although AWS offers a DynamoDB pricing calculator, it often misses the nuances of real-world workloads (e.g., bursty traffic or uneven access patterns, or using global tables or caching). We wanted something better. In full transparency, we wanted something better to help the teams considering ScyllaDB as a DynamoDB alternative. So we built a new DynamoDB cost calculator that helps developers understand what their workloads will really cost. Although we designed it for teams comparing DynamoDB with ScyllaDB, we believe it’s useful for anyone looking to more accurately estimate their DynamoDB costs, for any reason. You can see the live version at: calculator.scylladb.com How We Built It We wanted to build something that would work client side, without the need for any server components. It’s a simple JavaScript single page application that we currently host on GitHub pages. If you want to check out the source code, feel free to take a look at https://github.com/scylladb/calculator To be honest, working with the examples at https://calculator.aws/ was a bit of a nightmare, and when you “show calculations,” you get these walls of text: I was tempted to take a shorter approach, like: Monthly WCU Cost = WCUs × Price_per_WCU_per_hour × 730 hours/month But every time I simplified this, I found it harder to get parity between what I calculated and the final price in AWS’s calculation. Sometimes the difference was due to rounding, other times it was due to the mixture of reserved + provision capacity, and so on. So to make it easier (for me) to debug, I faithfully followed their calculations line by line and tried to replicate this in my own rather ugly function: https://github.com/scylladb/calculator/blob/main/src/calculator.js I may still refactor this into smaller functions. But for now, I wanted to get parity between theirs and ours. You’ll see that there are also some end-to-end tests for these calculations — I use those to test for a bunch of different configurations. I will probably expand on these in time as well. So that gets the job done for On Demand, Provisioned (and Reserved) capacity models. If you’ve used AWS’s calculator, you know that you can’t specify things like a peak (or peak width) in On Demand. I’m not sure about their reasoning. I decided it would be easier for users to specify both the baseline and peak for reads and writes (respectively) in On Demand, much like Provisioned capacity. Another design decision was to represent the traffic using a chart. I do better with visuals, so seeing the peaks and troughs makes it easier for me to understand – and I hope it does for you as well. You’ll also notice that as you change the inputs, the URL query parameters change to reflect those inputs. That’s designed to make it easier to share and reference specific variations of costs. There’s some other math in there, like figuring out the true cost of Global Tables and understanding derived costs of things like network transfer or DynamoDB Accelerator (DAX). However, explaining all that is a bit too dense for this format. We’ll talk more about that in an upcoming webinar (see the next section). The good news is that you can estimate these costs in addition to your workload, as they can be big cost multipliers when planning out your usage of DynamoDB. Explore “what if” scenarios for your own workloads Analyzing Costs in Real-World Scenarios The ultimate goal of all this tinkering and tuning is to help you explore various “what-if” scenarios from a DynamoDB cost perspective.  To get started, we’re sharing the cost impacts of some of the more interesting DynamoDB user scenarios we’ve come across at ScyllaDB. My colleague Gui and I just got together for a deep dive into how factors like traffic surges, multi-datacenter expansion, and the introduction of caching (e.g., DAX) impact DynamoDB costs. We explored how a few (anonymized) teams we work with ended up blindsided by their DynamoDB bills and the various options they considered for getting costs back under control. Watch the DynamoDB costs chat now

Cassandra vs. MongoDB: When to Use Which​​​​‌‍​‍​‍‌‍‌​‍‌‍‍‌‌‍‌‌‍‍‌‌‍‍​‍​‍​‍‍​‍​‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌‍‍‌‌‍​‍​‍​‍​​‍​‍‌‍‍​‌​‍‌‍‌‌‌‍‌‍​‍​‍​‍‍​‍​‍‌‍‍​‌‌​‌‌​‌​​‌​​‍‍​‍​‍‌‍‌​‌‍​‌‌‌​‌‍​‌‌​‌‌​‌‍​‌‌‍​​‍‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌​‌‌​‌‌‌‌‍‌​‌‍‍‌‌‍​‍‌‍‍‌‌‍‍‌‌​‌‍‌‌‌‍‍‌‌​​‍‌‍‌‌‌‍‌​‌‍‍‌‌‌​​‍‌‍‌‌‍‌‍‌​‌‍‌‌​‌‌​​‌​‍‌‍‌‌‌​‌‍‌‌‌‍‍‌‌​‌‍​‌‌‌​‌‍‍‌‌‍‌‍‍​‍‌‍‍‌‌‍‌​​‌‌‍‌‍‌‍‌‌​​‌‌‍‌‍​‌​​‌‌‍​‌‌‍​‌​‍‌‌‍​‌‌‍​‍​‍‌​​​​‍‌​‌​‌‍​‍​​‌​‌‌​‍‌​‍​​‍‌​‌​‌‍‌‍​‍‌​‌​‌​‌‌​‌‍​‌‌‌‍​​‍​​​‌‍‌‌‌‍​​​​‌‍‌‌​‍‌‌​‌‍‌‌​​‌‍‌‌​‌‌‍​‍‌‍​‌‍‌‍‌‌‌​​‌‍‌​‌‌​​‍‌​​‌‍​‌‌‌​‌‍‍​​‌‌‌​‌‍‍‌‌‌​‌‍​‌‍‌‌​‌‍​‍‌‍​‌‌​‌‍‌‌‌‌‌‌‌​‍‌‍​​‌‌‍‍​‌‌​‌‌​‌​​‌​​‍‌‌​​‌​​‌​‍‌‌​​‍‌​‌‍​‍‌‌​​‍‌​‌‍‌‍‌​‌‍​‌‌‌​‌‍​‌‌​‌‌​‌‍​‌‌‍​​‍‍‌​‌‍​‌‌‍‍‌‍‍‌‌‌​‌‍‌​‍‍‌​‌‌​‌‌‌‌‍‌​‌‍‍‌‌‍​‍‌‍‌‍‍‌‌‍‌​​‌‌‍‌‍‌‍‌‌​​‌‌‍‌‍​‌​​‌‌‍​‌‌‍​‌​‍‌‌‍​‌‌‍​‍​‍‌​​​​‍‌​‌​‌‍​‍​​‌​‌‌​‍‌​‍​​‍‌​‌​‌‍‌‍​‍‌​‌​‌​‌‌​‌‍​‌‌‌‍​​‍​​​‌‍‌‌‌‍​​​​‌‍‌‌​‍‌‍‌‌​‌‍‌‌​​‌‍‌‌​‌‌‍​‍‌‍​‌‍‌‍‌‌‌​​‌‍‌​‌‌​​‍‌‍‌​​‌‍​‌‌‌​‌‍‍​​‌‌‌​‌‍‍‌‌‌​‌‍​‌‍‌‌​‍‌‍‌​​‌‍‌‌‌​‍‌​‌​​‌‍‌‌‌‍​‌‌​‌‍‍‌‌‌‍‌‍‌‌​‌‌​​‌‌‌‌‍​‍‌‍​‌‍‍‌‌​‌‍‍​‌‍‌‌‌‍‌​​‍​‍‌‌

4 June 2025, 6:31 am by Datastax Technical HowTo's

Which NoSQL database works best for powering your GenAI use cases? A look at Cassandra vs. MongoDB and which to use when.

Rust Rewrite, Postgres Exit: Blitz Revamps Its “League of Legends” Backend

3 June 2025, 12:48 pm by ScyllaDB

How Blitz scaled their game coaching app with lower latency and leaner operations Blitz is a fast-growing startup that provides personalized coaching for games such as League of Legends, Valorant, and Fortnite. They aim to help gamers become League of Legends legends through real-time insights and post-match analysis. While players play, the app does quite a lot of work. It captures live match data, analyzes it quickly, and uses it for real-time game screen overlays plus personalized post-game coaching. The guidance is based on each player’s current and historic game activity, as well as data collected across billions of matches involving hundreds of millions of users. Thanks to growing awareness of Blitz’s popular stats and game-coaching app, their steadily increasing user base pushed their original Postgres- and Elixir-based architecture to its limits. This blog post explains how they recently overhauled their League of Legends data backend – using Rust and ScyllaDB. TL;DR – In order to provide low latency, high availability, and horizontal scalability to their growing user base, they ultimately: Migrated backend services from Elixir to Rust. Replaced Postgres with ScyllaDB Cloud. Heavily reduced their Redis footprint. Removed their Riak cluster. Replaced queue processing with realtime processing. Consolidated infrastructure from over a hundred cores of microservices to four n4‑standard‑4 Google Cloud nodes (plus a small Redis instance for edge caching) As an added bonus, these changes ended up cutting Blitz’s infrastructure costs and reducing the database burden on their engineering staff. Blitz Background As Naveed Khan (Head of Engineering at Blitz) explained, “We collect a lot of data from game publishers and during gameplay. For example, if you’re playing League of Legends, we use Riot’s API to pull match data, and if you install our app we also monitor gameplay in real time. All of this data is stored in our transactional database for initial processing, and most of it eventually ends up in our data lake.” Scaling Past Postgres One key part of Blitz’s system is the Playstyles API, which analyzes pre-game data for both teammates and opponents. This intensive process evaluates up to 20 matches per player and runs nine separate times per game (once for each player in the match). The team strategically refactored and consolidated numerous microservices to improve performance. But the data volume remained intense. According to Brian Morin (Principal Backend Engineer at Blitz), “Finding a database solution capable of handling this query volume was critical.” They originally used Postgres, which served them well early on. However, as their write-heavy workloads scaled, the operational complexity and costs on Google Cloud grew significantly. Moreover, scaling Postgres became quite complex. Naveed shared, “We tried all sorts of things to scale. We built multiple services around Postgres to get the scale we needed: a Redis cluster, a Riak cluster, and Elixir Oban queues that occasionally overflowed. Queue management became a big task.” To stay ahead of the game, they needed to move on. As startups scale, they often switch from “just use Postgres” to “just use NoSQL.” Fittingly, the Blitz team considered moving to MongoDB, but eventually ruled it out. “We had lots of MongoDB experience in the team and some of us really liked it. However, our workload is very write-heavy, with thousands of concurrent players generating a constant stream of data. MongoDB uses a single-writer architecture, so scaling writes means vertically scaling one node.” In other words, MongoDB’s primary-secondary architecture would create a bottleneck for their specific workload and anticipated growth. They then decided to move forward with RocksDB because of its low latency and cost considerations. Tests showed that it would meet their latency needs, so they performed the required data (re)modeling and migrated a few smaller games over from Postgres to RocksDB. However, they ultimately decided against RocksDB due to scale and high availability concerns. “Based on available data from our testing, it was clear RocksDB wouldn’t be able to handle the load of our bigger games – and we couldn’t risk vertically scaling a single instance, and then having that one instance go down,” Naveed explained. Why ScyllaDB One of their backend engineers suggested ScyllaDB, so they reached out and ran a proof of concept. They were primarily looking for a solution that can handle the write throughput, scales horizontally, and provides high availability. They tested it on their own hardware first, then moved to ScyllaDB Cloud. Per Naveed, “The cost was pretty close to self-hosting, and we got full management for free, so it was a no-brainer. We now have a significantly reduced Redis cluster, plus we got rid of the Riak cluster and Oban queues dependencies. Just write to ScyllaDB and it all just works. The amount of time we spend on infrastructure management has significantly decreased.” Performance-wise, the shift met their goal of leveling up the user experience … and also simplified life for their engineering teams. Brian added, “ScyllaDB proved exceptional, delivering robust performance with capacity to spare after optimization. Our League product peaks at around 5k ops/sec with the cluster reporting under 20% load. Our biggest constraint has been disk usage, which we’ve rolled out multiple updates to mitigate. The new system can now often return results immediately instead of relying on cached data, providing more up-to-date information on other players and even identifying frequent teammates. The results of this migration have been impressive: over a hundred cores of microservices have been replaced by just four n4-standard-4 nodes and a minimal Redis instance for caching. Additionally, a 3xn2-highmem ScyllaDB cluster has effectively replaced the previous relational database infrastructure that required significant computing resources.” High-Level Architecture of Blitz Server with Rust and ScyllaDB Rewriting Elixir Services into Rust As part of a major backend overhaul, the Blitz team began rethinking their entire infrastructure – beyond the previously described shift from Postgres to the high-performance and distributed ScyllaDB. Alongside this database migration, they also chose to sunset their Elixir-based services in favor of a more modern language. After careful evaluation, Rust emerged as the clear choice. “Elixir is great and it served its purpose well,” explained Naveed. “But we wanted to move toward something with broader adoption and a stronger systems-level ecosystem. Rust proved to be a robust and future-proof alternative.” Now that the first batch of Rust rewritten services are in production, Naveed and team aren’t looking back: “Rust is fantastic. It’s fast, and the compiler forces you to write memory-safe code upfront instead of debugging garbage-collection issues later. Performance is comparable to C, and the talent pool is also much larger compared to Elixir.”

Why We Changed ScyllaDB’s Data Streaming Approach

29 May 2025, 1:13 pm by ScyllaDB

How moving from mutation-based streaming to file-based streaming resulted in 25X faster streaming time Data streaming – an internal operation that moves data from node to node over a network – has always been the foundation of various ScyllaDB cluster operations. For example, it is used by “add node” operations to copy data to a new node in a cluster (as well as “remove node” operations to do the opposite). As part of our multiyear project to optimize ScyllaDB’s elasticity, we reworked our approach to streaming. We recognized that when we moved to tablets-based data distribution, mutation-based streaming would hold us back. So we shifted to a new approach: stream the entire SSTable files without deserializing them into mutation fragments and re-serializing them back into SSTables on receiving nodes. As a result, less data is streamed over the network and less CPU is consumed, especially for data models that contain small cells. Mutation-Based Streaming In ScyllaDB, data streaming is a low-level mechanism to move data between nodes. For example, when nodes are added to a cluster, streaming moves data from existing nodes to the new nodes. We also use streaming to decommission nodes from the cluster. In this case, streaming moves data from the decommissioned nodes to other nodes in order to balance the data across the cluster. Previously, we were using a streaming method called mutation-based streaming.   On the sender side, we read the data from multiple SSTables. We get a stream of mutations, serialize them, and send them over the network. On the receiver side, we deserialize and write them to SSTables. File-Based Streaming Recently, we introduced a new file-based streaming method. The big difference is that we do not read the individual mutations from the SSTables, and we skip all the parsing and serialization work. Instead, we read and send the SSTable directly to remote nodes. A given SSTable always belongs to a single tablet. This means we can always send the entire SSTable to other nodes without worrying about whether the SSTable contains unwanted data. We implemented this by having the Seastar RPC stream interface stream SSTable files on the network for tablet migration. More specifically, we take an internal snapshot of the SSTables we want to transfer so the SSTables won’t be deleted during streaming. Then, SSTable file readers are created for them so we can use the Seastar RPC stream to send the SSTable files over the network. On the receiver side, the file streams are written into SSTable files by the SSTable writers.       Why did we do this? First, it reduces CPU usage because we do not need to read each and every mutation fragment from the SSTables, and we do not need to parse mutations. The CPU reduction is even more significant for small cells, where the ratio of the amount of metadata parsed to real user data is higher. Second, the format of the SSTable is much more compact than the mutation format (since on-disk presentation of data is more compact than in-memory). This means we have less data to send over the network. As a result, it can boost the streaming speed rather significantly. Performance Improvements To quantify how this shift impacted performance, we compared the performance of mutation-based and file-based streaming when migrating tablets between nodes. The tests involved: 3 ScyllaDB nodes i4i.2xlarge 3 loaders t3.2xlarge 1 billion partitions Here are the results:   Note that file-based streaming results in 25 times faster streaming time. We also have much higher streaming bandwidth: the network bandwidth is 10 times faster with file-based streaming. As mentioned earlier, we have less data to send with file streaming. The data sent on the wire is almost three times less with file streaming. In addition, we can also see that file-based streaming consumes many fewer CPU cycles. Here’s a little more detail, in case you’re curious. Disk IO Queue The following sections show how the IO bandwidth compares across mutation-based and file-based streaming. Different colors represent different nodes. As expected, the throughput was higher with mutation-based streaming. Here are the detailed IO results for mutation-based streaming:   The streaming bandwidth is 30-40MB/s with mutation-based streaming. Here are the detailed IO results for file-based streaming: The bandwidth for file streaming is much higher than with mutation-based streaming. The pattern differs from the mutation-based graph because file streaming completes more quickly and can sustain a high speed of transfer bandwidth during streaming. CPU Load We found that the overall CPU usage is much lower for the file-based streaming. Here are the detailed CPU results for mutation-based streaming: Note that the CPU usage is around 12% for mutation-based streaming. Here are the detailed CPU results for file-based streaming: Note that the CPU usage for the file-based streaming is less than 5%. Again, this pattern differs from the mutation-based streaming graph because file streams complete much more quickly and can maintain a high transfer bandwidth throughout. Wrap Up This new file-based streaming makes data streaming in ScyllaDB faster and more efficient. You can explore it in ScyllaDB Cloud or ScyllaDB 2025.1. Also, our CTO and co-founder Avi Kivity shares an extensive look at our other recent and upcoming engineering projects in this tech talk: More engineering blog posts

The Strategy Behind ReversingLabs’ Monster Scale Key-Value Migration

20 May 2025, 1:02 pm by ScyllaDB

Migrating 300+ TB of data and 400+ services from a key-value database to ScyllaDB – with zero downtime ReversingLabs recently completed the largest migration in their history: migrating more than 300 TB of data, more than 400 services, and data models from their internally-developed key-value database to ScyllaDB seamlessly, and with zero downtime. Services using multiple tables — reading, writing, and deleting data, and even using transactions — needed to go through a fast and seamless switch. How did they pull it off? Martina recently shared their strategy, including data modeling changes, the actual data migration, service migration, and a peek at how they addressed distributed locking. Here’s her complete tech talk:   And you can read highlights below… About ReversingLabs Reversing Labs is a security company that aims to analyze every enterprise software package, container and file to identify potential security threats and mitigate cybersecurity risks. They maintain a library of 20B classified samples of known “goodware” (benign) and malware files and packages. Those samples are supported by ~300 TB of metadata, which are processed using a network of approximately 400 microservices. As Martina put it: “It’s a huge system, complex system – a lot of services, a lot of communication, and a lot of maintenance.” Never build your own database (maybe?) When the ReversingLabs team set out to select a database in 2011, the options were limited. Cassandra was at version 0.6, which lacked role-level isolation DynamoDB was not yet released ScyllaDB was not yet released MongoDB 1.6 had consistency issues between replicas PostgreSQL was struggling with multi-version concurrency control (MVCC), which created significant overhead “That was an issue for us—Postgres used so much memory,” Martina explained. “For a startup with limited resources, having a database that ate all our memory was a problem. So we built our own data store. I know, it’s scandalous—a crazy idea today—but in this context, in this market, it made sense.” The team built a simple key-value store tailored to their specific needs—no extra features, just efficiency. It required manual maintenance and was only usable by their specialized database team. But it was fast, used minimal resources, and helped ReversingLabs, as a small startup, handle massive amounts of data (which became a core differentiator). However, after 10 years, ReversingLabs’ growing complexity and expanding use cases became overwhelming – to the database itself and the small database team responsible for it. Realizing that they reached their home-grown database’s tipping point, they started exploring alternatives. Enter ScyllaDB. Martina shared: “After an extensive search, we found ScyllaDB to be the most suitable replacement for our existing database. It was fast, resilient, and scalable enough for our use case. Plus, it had all the features our old database lacked. So, we decided on ScyllaDB and began a major migration project.” Migration Time The migration involved 300 TB of data, hundreds of tables, and 400 services. The system was complex, so the team followed one rule: keep it simple. They made minimal changes to the data model and didn’t change the code at all. “We decided to keep the existing interface from our old database and modify the code inside it,” Martina shared. “We created an interface library and adapted it to work with the ScyllaDB driver. The services didn’t need to know anything about the change—they were simply redeployed with the new version of the library, continuing to communicate with ScyllaDB instead of the old database.” Moving from a database with a single primary node to one with a leaderless ring architecture did require some changes, though. The team had to adjust the primary key structure, but the value itself didn’t need to be changed. In the old key-value store, data was stored as a packed protobuf with many fields. Although ScyllaDB could unpack these protobufs and separate the fields, the team chose to keep them as they were to ensure a smoother migration. At this point, they really just wanted to make it work exactly like before. The migration had to be invisible — they didn’t want API users to notice any differences. Here’s an overview of the migration process they performed once the models were ready: 1. Stream the old database output to Kafka The first step was to set up a Kafka topic dedicated to capturing updates from the old database. 2. Dump the old database into a specified location Once the streaming pipeline was in place, the team exported the full dataset from the old database. 3. Prepare a ScyllaDB table by configuring its structure and settings Before loading the data, they needed to create a ScyllaDB table with the new schema. 4. Prepare and load the dump into the ScyllaDB table With the table ready, the exported data was transformed as needed and loaded into ScyllaDB. 5. Continuously stream data to ScyllaDB They set up a continuous pipeline with a service that listened to the Kafka topic for updates and loaded the data into ScyllaDB. After the backlog was processed, the two databases were fully in sync, with only a negligible delay between the data in the old database and ScyllaDB. It’s a fairly straightforward process…but it had to be repeated for 100+ tables. Next Up: Service Migration The next challenge was migrating their ~400 microservices. Martina introduced the system as follows: “We have master services that act as data generators. They listen for new reports from static analysis, dynamic analysis, and other sources. These services serve as the source of truth, storing raw reports that need further processing. Each master service writes data to its own table and streams updates to relevant queues. The delivery services in the pipeline combine data from different master services, potentially populating, adding, or calculating something with the data, and combining various inputs. Their primary purpose is to store the data in a format that makes it easy for the APIs to read. The delivery services optimize the data for queries and store it in their own database, while the APIs then read from these new databases and expose the data to users.” Here’s the 5-step approach they applied to service migration: 1. Migrate the APIs one by one The team migrated APIs incrementally. Each API was updated to use the new ScyllaDB-backed interface library. After redeploying each API, the team monitored performance and data consistency before moving on to the next one. 2. Prepare for the big migration day Once the APIs were migrated, they had to prepare for the big migration day. Since all the services before the APIs are intertwined, they all had to be migrated all at once. 3. Stop the master services On migration day, the team stopped the master services (data generators), causing input queues to accumulate until the migration was complete. During this time, the APIs continued serving traffic without any downtime. However, the data in the databases was delayed for about an hour or two until all services were fully migrated. 4. Migrate the delivery services After stopping the master services, the team waited for the queues between the master and delivery services to empty – ensuring that the delivery services processed all data and stopped writing. The delivery services were then migrated one by one to the new database. There was no data at this point because the master services were stopped. 5. Migrate and start the master services At last, it was time to migrate and start the master services. The final step was to shut down the old database because everything was now working on ScyllaDB. “It worked great, Martina shared. “We were happy with the latencies we achieved. If you remember, our old architecture had a single master node, which created a single point of failure. Now, with ScyllaDB, we had resiliency and high availability, and we were quite pleased with the results.” And Finally…Resource Locking One final challenge: resource locking. Per Martina, “In the old architecture, resource locking was simple because there was a single master node handling all writes. You could just use a mutex on the master node, and that was it—locking was straightforward. Of course, it needed to be tied to the database connection, but that was the extent of it.” ScyllaDB’s leaderless architecture meant that the team had to figure out distributed locking. They leveraged ScyllaDB’s lightweight transactions and built a distributed locking mechanism on top of it. The team worked closely with ScyllaDB engineers, going through several proofs of concept (POCs)—some successful, others less so. Eventually, they developed a working solution for distributed locking in their new architecture. You can read all the details in Martina’s blog post, Implementing distributed locking with ScyllaDB.  

Efficient Full Table Scans with ScyllaDB Tablets

13 May 2025, 12:30 pm by ScyllaDB

“Tablets” data distribution makes full table scans on ScyllaDB more performant than ever Full scans are resource-intensive operations reading through an entire dataset. They’re often required by analytical queries such as counting total records, identifying users from specific regions, or deriving top-K rankings. This article describes how ScyllaDB’s shift to tablets significantly improves full scan performance and processing time, as well as how it eliminates the complex tuning heuristics often needed with the previous vNodes based approach. It’s been quite some time since we last touched on the subject of handling full table scans on ScyllaDB. Previously, Avi Kivity described how the CQL token() function could be used in a divide and conquer approach to maximize running analytics on top of ScyllaDB. We also provided sample Go code and demonstrated how easy and efficient full scans could be done. With the recent introduction of tablets, it turns out that full scans are more performant than ever. Token Ring Revisited Prior to tablets, nodes in a ScyllaDB cluster owned fractions of the token ring, also known as token ranges. A token range is nothing more than a contiguous segment represented by two (very large) numbers. By default, each node used to own 256 ranges, also known as vNodes. When data gets written to the cluster, the Murmur3 hashing function is responsible for distributing data to replicas of a given token range. A full table scan thus involved parallelizing several token ranges until clients eventually traverse the entire ring. As a refresher, a scan involves iterating through multiple subranges (smaller vNode ranges) with the help of the token() function, like this: SELECT ... FROM t WHERE token(key) >= ? AND token(key) < ? To fully traverse the ring as fast as possible, clients needed to keep parallelism high enough (number of nodes x shard count x some smudge factor) to fully benefit from all available processing power. In other words, different cluster topologies would require different parallelism settings, which could often change as nodes got added or removed. Traversing vNodes worked nicely, but the approach introduced some additional drawbacks, such as: Sparse tables result in wasted work because most token ranges contain little or no data. Popular and high-density ranges could require fine-grained tuning to prevent uneven load distribution and resource contention. Otherwise, they would be prone to processing bottlenecks and suboptimal utilization. It was impossible to scan a token range owned by a single shard, and particularly difficult to even scan a range owned by a single replica. This increases coordination overhead, and creates a performance ceiling on how fast a single token range could be processed. The old way: system.size_estimates To assist applications during range scans, ScyllaDB provided a node-local system.size_estimates table (something we inherited from Apache Cassandra) whose schema looks like this: CREATE TABLE system.size_estimates ( keyspace_name text, table_name text, range_start text, range_end text, mean_partition_size bigint, partitions_count bigint, PRIMARY KEY (keyspace_name, table_name, range_start, range_end) ) Every token range owned by a given replica provides an estimated number of partitions along with a mean partition size. The product of both columns therefore provides a raw estimate on how much data needs to be retrieved if a scan reads through the entire range. This design works nicely under small clusters and when data isn’t frequently changing. Since the data is node local, an application in charge of the full scan would be required to keep track of 256 vNodes*Node entries to submit its queries. Therefore, larger clusters could introduce higher processing overhead. Even then, (as the table name suggests) the number of partitions and their sizes are just estimates, which can be underestimated or overestimated. Underestimating a token range size makes a scan more prone to timeouts, particularly when its data contains a few large partitions along many smaller sized keys. Overestimating it means a scan may take longer to complete due to wasted cycles while scanning through sparse ranges. Parsing the system.size_estimates table’s data is precisely what connectors like Trino and Spark do when you integrate them with either Cassandra or ScyllaDB. To address estimate skews, these tools often allow you to manually tune settings like split-size in a trial-and-error fashion until it somewhat works for your workload. Its rationale works like this: Clients parse the system.size_estimates data from every node in the cluster (since vNodes are non overlapping ranges, fully describing the ring distribution) The size of a specific range is determined by partitionsCount * meanPartitionSize It then calculates the estimated number of partitions and the size of the table to be scanned It evenly splits each vNode range into subranges, taking its corresponding ring fraction into account Subranges are parallelized across workers and routed to natural replicas as an additional optimization Finally, prior to tablets there was no deterministic way to scan a particular range and target a specific ScyllaDB shard. vNodes have no 1:1 token/shard mapping, meaning a single coordinator request would often need to communicate with other replica shards, making it particularly easier to introduce CPU contention. A layer of indirection: system.tablets Starting with ScyllaDB 2024.2, tablets are production ready. Tablets are the foundation behind ScyllaDB elasticity, while also effectively addressing the drawbacks involved with full table scans under the old vNode structure. In case you missed it, I highly encourage you to watch Avi Kivity talk on Tablets: Rethinking Replication for an in-depth understanding on how tablets evolved from the previous vNodes static topologies. During his talk, Avi mentions that tablets are implemented as a layer of indirection involving a token range to a (replica, shard) tuple. This layer of indirection is exposed in ScyllaDB as the system.tablets table, whose schema looks like this: CREATE TABLE system.tablets ( table_id uuid, last_token bigint, keyspace_name text STATIC, resize_seq_number bigint STATIC, resize_type text STATIC, table_name text STATIC, tablet_count int STATIC, new_replicas frozen<list<frozen<tuple<uuid, int>>>>, replicas frozen<list<frozen<tuple<uuid, int>>>>, session uuid, stage text, transition text, PRIMARY KEY (table_id, last_token) ) A tablet represents a contiguous token range owned by a group of replicas and shards. Unlike the previous static vNode topology, tablets are created on a per table basis and get dynamically split or merged on demand. This is important, because workloads may vary significantly: Some are very throughput intensive under frequently accessed (and small) data sets and will have fewer tablets. These take less time to scan. Others may become considerably storage bound over time, spanning through multiple terabytes (or even petabytes) of disk space. These take longer to scan. A single tablet targets a geometric average size of 5GB before it gets split. Therefore, splits are done when a tablet reaches 10GB and merges at 2.5GB. Note that the average size is configurable, and the default might change in the future. However, scanning over each tablet owned range allows full scans to deterministically determine up to how much data they are reading. The only exception to this rule is when very large (larger than the average) partitions are involved, although this is an edge case. Consider the following set of operations: In this example, we start by defining that we want tables within the ks keyspace to start with 128 tablets each. After we create table t, observe that the tablet_count matches what we’ve set upfront. If we had asked for a non base 2 number, the tablet_count would be rounded to the next base 2 number. The tablet_count represents the total number of tablets across the cluster, where the replicas column represents a tuple of host IDs/shards which are replicas of that tablet, matching our defined replication factor. Therefore, the previous logic can be optimized like this: Clients parse the system.tablets table and retrieve the existing tablet distribution Tablets ranges spanning the same replica-shards get grouped and split together Workers route requests to natural replica/shard endpoints via shard awareness by setting a routingKey for every request. Tablet full scans have lots to benefit from these improvements. By directly querying specific shards, we eliminate the cost of cross CPU and node communication. Traversing the ring is not only more efficient, but effectively removes the problem with sparse ranges and different tuning logic for small and large tables. Finally, given that a tablet has a predetermined size, long gone are the days of fine-tuning splitSizes! Example This GitHub repo contains boilerplate code demonstrating how to carry out these tasks efficiently. The process involves splitting tablets into smaller pieces of work, and scheduling them evenly across its corresponding replica/shards. The scheduler ensures that replica shards are kept busy with at least 2 inflight requests each, whereas the least loaded replica always consumes pending work for processing. The code also simulates real-world latency variability by introducing some jitter during each request processing. [Access from the GitHub repo] Conclusion This is just the beginning of our journey with tablets. The logic explained in this blog is provided for application builders to follow as part of their full scan jobs. It is worth mentioning that the previous vNode technique is backward compatible and still works if you use tablets. Remember that full scans often require reading through lots of data, and we highly recommend you to use BYPASS CACHE to prevent invalidating important cached rows. Furthermore, ScyllaDB Workload Prioritization helps with isolation and ensures latencies from concurrent are kept low. Happy scanning!